JP2005118207A - Ultraviolet irradiator and ultraviolet irradiation unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a portable ultraviolet irradiator capable of irradiating a desired position. <P>SOLUTION: An irradiation unit 14 is incorporated in a portable case body 12, and the irradiation unit 14 is provided with an ultraviolet LED 16 for emitting ultraviolet rays and a red LED 18 for emitting visible light. The red LED 18 is arranged such that a light converging point roughly matches with the ultraviolet ray LED 16. The ultraviolet rays and the visible light are converged by a lens 24, made to pass through the same optical path and emitted. Thus, the optical path and irradiation position of the ultraviolet rays can be estimated from the optical path and the irradiation position of the visible light. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an ultraviolet irradiation device that emits ultraviolet rays and an irradiation unit thereof, and more particularly to a portable ultraviolet irradiation device and an irradiation unit thereof.

  Conventionally, various ultraviolet irradiation apparatuses have been proposed. For example, a table-type ultraviolet irradiation device for use in nail decoration (nail art) with an ultraviolet curable resin is known. This ultraviolet irradiation device for decorating nails employs an ultraviolet fluorescent lamp as an ultraviolet light source. Since the ultraviolet fluorescent lamp itself has a certain size, the entire apparatus becomes a desktop size.

  However, in recent years, small ultraviolet light emitters such as ultraviolet LEDs (Light Emitting Diodes) and ultraviolet LDs (Laser Diodes) have been put into practical use. By using these, a portable ultraviolet irradiation device can be realized.

  For example, there is a fluorescent writing instrument kit disclosed in Patent Document 1 using this small ultraviolet light emitter. This is a writing instrument provided with an ultraviolet irradiation tool for visually recognizing a writing line written with special ink that cannot be visually recognized under visible light such as fluorescent ink. An ultraviolet irradiator is attached to one end of the writing instrument of special ink, and after writing with the writing instrument, the written content can be visually recognized by irradiating with ultraviolet rays.

JP 2003-237283 A

  However, since the ultraviolet light irradiation device for nail decoration uses a linear light source called an ultraviolet fluorescent lamp, it is difficult to irradiate only one nail or a part of the nail in the nail decoration. In order to perform partial irradiation, it was necessary to partially block ultraviolet rays using a mask or the like, which was extremely inconvenient. Moreover, since it is a desktop size, it is difficult to carry around, or a stand for mounting is required at the time of use.

  On the other hand, the fluorescent writing instrument kit disclosed in Patent Document 1 is portable and can be partially irradiated by using a small ultraviolet light emitter (ultraviolet LED). By the way, in the fluorescent writing instrument kit of patent document 1, since the presence or absence of ultraviolet irradiation is determined by whether or not the writing line can be visually recognized, it is not necessary to know the ultraviolet irradiation position. Therefore, the fluorescent writing instrument kit is not provided with means for recognizing the ultraviolet irradiation position. However, in a nail decoration or the like, a means for recognizing the irradiation position is required when it is desired to appropriately irradiate a desired position. Therefore, the fluorescent writing instrument kit not provided with means for recognizing the ultraviolet irradiation position is not suitable for nail decoration.

  Therefore, an object of the present invention is to provide a portable ultraviolet irradiation device and an irradiation unit that can irradiate a desired position.

  The ultraviolet irradiation device of the present invention has a portable housing, an ultraviolet light emitter incorporated in the housing, and a guide means that makes it possible to visually recognize at least a part of an irradiation light path of ultraviolet rays by the ultraviolet light emitter. It is characterized by.

  In a preferred embodiment, the guide means is a light transmission member that guides ultraviolet rays emitted from the ultraviolet light emitter. As the light transmission member, a light guide rod or an optical fiber is desirable.

  In another preferred embodiment, the guiding means is a visible light emitter that irradiates the vicinity of the irradiation position of ultraviolet rays. It is desirable that the visible light emitter can be temporarily turned off while the ultraviolet light emitter is turned on. The visible light emitter preferably has at least one color of red, green, and blue.

  In another preferred embodiment, the light emitting device includes a light collecting unit including a lens for collecting ultraviolet rays and a distance adjusting unit for adjusting the distance between the ultraviolet light emitter and the lens.

  In another preferred embodiment, a plurality of switches for lighting the ultraviolet light emitter are provided, and the ultraviolet light emitter is turned on only when all the switches are in the on state. Desirably, it is desirable to have a safety switch that is turned on only when the ultraviolet irradiation port provided in the housing is lowered by a predetermined angle from the horizontal direction.

  In another preferred embodiment, a timer that can set the lighting time of the ultraviolet light emitter is provided. Moreover, in another suitable aspect, the applicator for apply | coating the special resin which changes a property by irradiation of an ultraviolet-ray is provided in the housing | casing. Desirably, a photocatalyst is provided in the reach of ultraviolet rays emitted from the ultraviolet light emitter.

  Another ultraviolet irradiation apparatus according to the present invention is an ultraviolet irradiation apparatus for performing nail decoration by curing an ultraviolet curable resin for nail decoration by irradiating with ultraviolet light. An ultraviolet light emitter that emits ultraviolet light, and a guide unit that makes it possible to visually recognize at least a part of a light irradiation path of the ultraviolet light emitted from the ultraviolet light emitter.

  Another ultraviolet irradiation unit according to the present invention is an ultraviolet irradiation unit that can be incorporated in a portable housing, and can visually recognize at least a part of an ultraviolet light emitting body that emits ultraviolet light and an ultraviolet light irradiation path by the ultraviolet light emitting body. And a guide means comprising an optical fiber or a light guide rod for guiding the ultraviolet rays emitted from the ultraviolet light emitter.

  Another ultraviolet irradiation unit according to the present invention is an ultraviolet irradiation unit that can be incorporated in a portable housing, and can visually recognize at least a part of an ultraviolet light emitting body that emits ultraviolet light and an ultraviolet light irradiation path by the ultraviolet light emitting body. And a guide means that is a visible light emitter provided at a position capable of irradiating the vicinity of the ultraviolet irradiation position.

  According to the present invention, since at least a part of the irradiation light path of ultraviolet rays can be confirmed, it is possible to irradiate a desired position while estimating the irradiation position.

  Embodiments of the present invention will be described below with reference to the drawings. In the following description, an apparatus suitable for this is described assuming that it is particularly used for nail decoration (nail art). However, it can be used for other purposes by appropriately changing the shape and members.

  In FIG. 1, the side view of the ultraviolet irradiation device 10 which is embodiment of this invention is shown. This ultraviolet irradiation device 10 is a portable housing 12 with a built-in irradiation unit 14 for ultraviolet irradiation.

  The housing 12 is a substantially cylindrical pen type, and is large enough to be held with one hand. In addition to the irradiation unit 14 for ultraviolet irradiation, a dry battery (not shown) serving as a power source, a safety switch 30 and the like are incorporated. The shape of the housing 12 is not limited to the pen type, and may be any other shape and size as long as it is portable.

  The irradiation unit 14 includes an ultraviolet LED 16 that is an ultraviolet light emitter and a red LED 18 that is a visible light emitter. These two types of LEDs are held by the holder 20 and are built in the housing 12.

  Here, in this embodiment, a red LED is used as the visible light emitter, but other colors may be emitted as long as they emit visible light. However, the visible light is a guide means for visually recognizing a part of the ultraviolet light path, as will be described later. Therefore, it is desirable to have a color (wavelength) different from ambient light so that it can be easily recognized. For example, in addition to red, green and blue are suitable. Further, even if the color (wavelength) is the same as or similar to the ambient light, it can be used as a guide means by adjusting the luminance or the like.

  Moreover, as long as it is a light-emitting body which can be incorporated in the housing | casing 12, LD (Laser Diode) other than LED (Light Emitting Diode) etc. may be sufficient. Alternatively, a single ultraviolet LED in which an ultraviolet LED chip and a visible LED chip are arranged and mounted may be used. Further, a plurality of visible light LEDs and ultraviolet LEDs may be provided. At that time, different colors may be mixed in the visible light LED. For example, a plurality of visible light LEDs of different colors may be provided so that the visible light LEDs irradiated according to the color of the irradiation target portion can be switched.

  The irradiation unit 14 can employ various arrangements as shown in FIGS. For example, as shown in FIG. 2, the two types of LEDs 16 and 18 may be arranged so as to be symmetric about the holder central axis 32. At this time, the optical axes 34 and 35 of the LEDs intersect with each other on the holder center axis 32, and the intersection P is the condensing point of each LED. That is, the ultraviolet LED 16 and the red LED 18 are arranged so that their condensing points substantially coincide.

  Moreover, as shown in FIG. 3, the optical axis 34 of the ultraviolet LED 16 may be parallel to the holder central axis (not shown), and the optical axis 35 of the red LED 18 may be disposed at a predetermined angle. At this time, the optical axes 34 and 35 of the LEDs intersect with each other on the ultraviolet optical axis 34, and the intersection P is the condensing point of each LED. That is, the ultraviolet LED 16 and the red LED 18 are arranged so that their condensing points substantially coincide.

  Thus, by arranging the condensing points of the ultraviolet rays and the visible light so as to substantially coincide with each other, the condensing points of the visible light can be recognized as the condensing points of the ultraviolet rays. And an ultraviolet irradiation position can be estimated based on the condensing point of the visible light.

  Furthermore, as shown in FIG. 4, a plurality of, for example, three red LEDs 18 may be provided on the outer periphery of the ultraviolet LED 16 so as to be rotationally symmetric. According to this arrangement, the center of the plurality of visible light irradiation positions can be recognized as the ultraviolet irradiation position. The plurality of visible light LEDs may include different color LEDs.

  Furthermore, as shown in FIG. 5, a light guide plate 36 may be provided on the outer periphery of the ultraviolet LED 16, and the red LED 18 may be disposed at a position where the light guide plate 36 can be irradiated. According to this arrangement, the center of visible light irradiated in a ring shape can be recognized as an ultraviolet irradiation position. The light guide plate is not limited to an annular shape as long as it has a rotationally symmetric shape (for example, a cross or a triangle) around the ultraviolet LED 16.

  Next, the light collecting unit 22 including the lens 24 will be described (see FIG. 1). Ultraviolet light and visible light emitted from the irradiation unit 14 are collected by the lens 24 and irradiated. The lens 24 is held by a lens holder (not shown) and attached to the front end surface of the housing 12. The ultraviolet rays and visible light collected by the lens 24 are irradiated through substantially the same optical path with the lens end serving as the irradiation port 25.

  In addition, as shown in FIG. 6, you may employ | adopt the condensing unit 22 which can adjust the distance of the lens 24 and a light source (ultraviolet LED16 and red LED18). In this case, the distance to the light source can be changed by rotating the condensing unit 22. A female screw 38 a is provided inside the housing 38 of the light collecting unit 22, and a male screw 12 a that can be screwed to the main body side housing 12 is formed. And the main body side housing | casing 12 and the condensing unit 22 are connected by the screwing of these internal thread 38a and external thread 12a. The pair of female screws 38a and male screws 12a function as a distance adjusting mechanism for adjusting the distance between the lens 24 and the light source. That is, by rotating the condensing unit 22 relative to the main body, the screw advances and the distance between the lens 24 and the light source can be changed. Using this action, the distance between the lens 24 and the light source can be adjusted as appropriate.

  When such a distance adjusting mechanism is provided, the irradiation area can be adjusted. That is, the focal length changes due to the change in the distance between the lens 24 and the light source, and the irradiation area to the irradiation object 40 at the same position changes. Therefore, the user can adjust the irradiation area by appropriately changing the distance between the lens 24 and the light source by the distance adjusting mechanism. The distance adjusting mechanism may be a mechanism other than the above as long as it is a mechanism for adjusting the distance between the ultraviolet light emitter and the lens.

  Turning on and off the ultraviolet light and visible light are operated by two types of switches 26 and 28 provided on the surface of the housing 12 and a safety switch 30 provided inside the housing 12 (see FIG. 1). On the surface of the housing 12, a rotary switch 26 as a main switch and a push switch 28 as a sub switch are provided. The rotary switch 26 is provided near the center of the housing 12 and is switched between an on state and an off state by the rotation of the housing 12.

  The push switch 28, which is a sub switch, is provided on the side wall of the housing 12 at a position close to the ultraviolet irradiation port 25. The push switch 28 is turned on only while being pressed, and is turned off when the pressing is stopped. This is to prevent forgetting to turn off the switch.

  The main switch 26 and the sub switch 28 may be other types of switches. For example, the main switch may be a rotary type, a slider type or a knock type. However, it is desirable that the switch is of a type that does not accidentally turn on when the device is carried in a bag or the like. Further, the sub switch may be a normal push switch (a switch that remains on even after being pressed and released), a touch sensor, or the like. However, a switch that can be operated with one hand, preferably with one finger, is desirable.

  The safety switch 30 is a switch that is provided inside the housing 12 and is turned on when the irradiation port 25 is directed downward from the horizontal direction. A sectional view of the safety switch 30 is shown in FIG. The safety switch 30 includes a weight 52 slidable inside the cavity 50 and a pair of contacts 56 provided on the wall 54 on the irradiation port side of the cavity 50.

  The cavity 50 is provided inside the housing 12 and has a cylindrical shape extending in the front-rear direction. The wall of the cavity 50 is made of an insulating material. A pair of contacts 56 (electrodes) are provided on the wall 54 (bottom surface and side surface) on the irradiation port side. The pair of contacts 56 is connected to a circuit for lighting the ultraviolet LED 16 and the red LED 18.

  The weight 52 has a cylindrical shape slightly smaller in diameter than the cavity 50 and can slide back and forth in the cavity 50 according to the posture of the housing 12. The weight 52 is made of a conductive material.

  The movement of the safety switch 30 having such a configuration will be described. When the irradiation port 25 is moved downward from the horizontal (the casing 12 is tilted), the weight 52 slides toward the irradiation port side by gravity and contacts the pair of contacts 56. When the conductive weight 52 comes into contact with both contact points 56, the contact point 56 becomes conductive, and the safety switch 30 is turned on.

  The shapes of the cavity 50 and the weight 52 can be changed as appropriate. For example, as shown in FIG. 8, the side surface of the cavity 50 may be inclined by a predetermined angle α, and the weight may be a metal ball 52. At this time, the pair of contacts 56 are provided on the side surface and bottom surface of the cavity 50 on the irradiation port side.

  In this way, by providing the cavity side wall with an inclination of a predetermined angle α, the irradiation state cannot be turned on unless the irradiation port is directed downward by an inclination angle α of the side wall or more. That is, since the side wall is inclined, the weight (the metal ball 52) does not move to the contact 56 unless the housing 12 is inclined (the irradiation port 25 is directed downward) by an inclination angle α or more of the side wall. Therefore, the angle at which the safety switch is turned on can be adjusted by appropriately adjusting the inclination angle α of the side wall. In particular, when the present apparatus is used for nail decoration (nail art) or the like, it is necessary to irradiate ultraviolet rays from various angles depending on the position and angle of an irradiation target portion such as a nail. In such a case, by adjusting the inclination angle of the side wall in advance to adjust the angle at which ultraviolet rays can be irradiated, the risk of erroneous irradiation and the like can be further reduced. In addition to the inclination angle of the side wall of the cavity, the inclination angle necessary for turning on by adjusting the friction coefficient of the side wall of the cavity may be adjusted.

  As described above, although three types of switches are provided in the present embodiment, the number of switches is not limited to three, and fewer or more switches may be provided.

  Next, a connection circuit between the plurality of switches 26, 28, 30 and the irradiation unit 14 is shown in FIG. A power source 58 that is a dry battery is connected to the ultraviolet LED 16 and the red LED 18 via the main switch 26, the safety switch 30, and the push switch 28. The ultraviolet LED 16 and the red LED 18 are connected in parallel, and are turned on and off in conjunction with each other. In addition, as long as the ultraviolet LED 16 and the red LED 18 are lit in conjunction, they may be connected in series.

  With this circuit configuration, if all the switches 26, 28, 30 are not turned on, power is not supplied to the LEDs 16, 18, and the LEDs 16, 18 are not lit. Therefore, even if one switch is mistakenly turned on, ultraviolet rays are not irradiated, and erroneous irradiation such as irradiating the eyes with ultraviolet rays can be prevented. Moreover, since the safety switch 30 is turned off when the irradiation port is upward, the upward irradiation of ultraviolet rays is prevented, and the risk of ultraviolet irradiation to the eyes can be further reduced.

  Furthermore, since the ultraviolet LED 16 and the red LED 18 are lit in conjunction with each other, the red LED 18 is also lit when the ultraviolet LED 16 is lit. Thereby, the lighting condition of ultraviolet LED16 can be confirmed visually. Therefore, it is possible to easily detect ultraviolet irradiation due to erroneous operation.

  However, when the red LED 18 having a color different from the ambient light is used for irradiation, it is difficult to understand the original color of the irradiated portion. In particular, when used for decoration or art such as nail decoration, the original color of the irradiated portion (the nail in nail decoration) is extremely important. Therefore, the red LED 18 may be blinked at predetermined intervals while the ultraviolet LED 16 is lit, so that the color of the ultraviolet irradiation target portion can be confirmed. Alternatively, another push switch may be provided for the red LED 18, and the red LED 18 may be turned off only while the switch is being pressed. Alternatively, the ultraviolet LED 16 and the red LED 18 may not be interlocked and may be configured by completely separate circuits. First, only the red LED 18 is turned on to confirm the ultraviolet irradiation position, and then the ultraviolet LED 16 may be operated to perform ultraviolet irradiation. While being irradiated with ultraviolet rays, the visible light LED may be in the off state or in the on state.

  Alternatively, the ultraviolet LED 16 may emit pulses every time all the switches 26, 28, 30 are turned on. By using pulsed light emission, erroneous irradiation due to forgetting to switch off can be further reduced. Moreover, instantaneous light emission intensity of ultraviolet rays can be increased by using pulsed light. Therefore, it is possible to increase the curing speed of the special resin that is cured by the ultraviolet irradiation, or to adjust the curing time.

  Next, a case where nail decoration is performed using the ultraviolet irradiation device 10 will be described with reference to FIG. When performing nail decoration, a special resin is applied to the surface of the nail 40 in advance. This special resin is cured by irradiation with ultraviolet rays, and is colored or contains decorative items (lamé or pearl) for nail decoration. Further, after application of the special resin, decorations such as beads and seals may be placed on the surface of the nail 40. Moreover, in order to protect the finger from the reaction heat generated when the special resin is cured, a base having high thermal conductivity may be applied or pasted to the nail in advance. The base is preferably made of a material having high thermal conductivity. For example, a metal foil or a paste containing metal powder can be used.

  In this state, as shown in FIG. 10, the apparatus 10 irradiates the special resin on the nail surface with ultraviolet rays. When performing ultraviolet irradiation, first, the rotary switch 26 which is a main switch is rotated to be turned on. Next, the safety switch 30 is turned on by holding the irradiation port 25 downward. Then, the push switch 28 is pressed to irradiate ultraviolet rays.

  At this time, although the ultraviolet ray itself cannot be visually recognized, red visible light having substantially the same optical path as the ultraviolet optical path 42 is also irradiated. Therefore, the user estimates the ultraviolet irradiation position while referring to the optical path and irradiation position of visible light, and adjusts the position of the irradiation port 25. Further, the irradiation area can be adjusted by changing the distance between the lens 24 and the irradiation portion 40 (if there is a distance adjustment mechanism, the distance adjustment mechanism may be adjusted). Also in this irradiation area adjustment, the irradiation area of red visible light is referred. Further, even during ultraviolet irradiation, ultraviolet light can be irradiated while confirming the color on the nail surface (under natural light) by appropriately turning off visible light.

  In this way, the ultraviolet curable resin on the surface of the nail 40 is cured by performing ultraviolet irradiation for a predetermined time while adjusting the irradiation position and area. Thereby, on the surface of the nail | claw 40, the outstanding coloring and glossiness are given. In addition, the decoration placed on the nail after the resin application is fixed on the nail by hardening of the resin.

  As described above, the apparatus 10 is portable and can be irradiated with ultraviolet rays at a desired location by being carried. Moreover, since the optical path and irradiation position of ultraviolet rays can be estimated from the optical path and irradiation position of visible light, a desired position can be irradiated with ultraviolet rays.

  Although the case of nail decoration has been described here, the present apparatus is not limited to the nail decoration, and may be used for manufacturing a shaped article using an ultraviolet curable resin. Further, not only the ultraviolet curable resin but also a special resin whose properties change due to ultraviolet irradiation, such as color change by ultraviolet rays, may be irradiated with ultraviolet rays.

  Next, another embodiment will be described with reference to FIG. FIG. 11 is a schematic configuration diagram of an ultraviolet irradiation apparatus 10 according to another embodiment. The ultraviolet irradiation device 10 includes a timer 60 in addition to the ultraviolet irradiation unit 14 and three types of switches.

  A display unit 62 and an operation unit 64 of the timer 60 are provided on the surface of the housing 12. The display unit 62 displays the set time. The operation unit 64 includes a plurality of buttons, and can perform operations such as time setting and resetting. The timer 60 is connected to the lighting circuit of the irradiation unit 14, and the ultraviolet LED 16 and the red LED 18 are automatically turned off when the set time has elapsed.

  When performing nail decoration using the apparatus 10, the user sets the irradiation time in the timer 60 in advance. The irradiation time set here is a time required to cure the ultraviolet curable resin. In other words, the ultraviolet curable resin has a certain amount of time required for curing depending on the energy of the irradiated ultraviolet rays and the type of the resin. Therefore, the user sets the time required for curing as the irradiation time of the ultraviolet rays according to the type of resin used.

  And after setting irradiation time to the timer 60, ultraviolet irradiation is started. When irradiation is started, time measurement by a timer is started. When the set time elapses, the ultraviolet LED 16 and the red LED 18 are automatically turned off. This prevents excessive irradiation and insufficient irradiation.

  By using the timer 60 in this way, excessive irradiation and insufficient irradiation can be prevented.

  Next, another embodiment will be described. FIG. 12 shows a schematic configuration diagram of an ultraviolet irradiation apparatus 10 according to another embodiment. The ultraviolet irradiation device 10 includes an applicator 66 and a resin cartridge 68 on the end surface opposite to the irradiation port 25.

  The applicator 66 is provided so as to protrude from the end surface opposite to the irradiation port 25, and the tip portion thereof is a brush. This brush is used to apply special resin to nails and the like.

  The applicator 66 is connected to a resin cartridge 68 housed in the housing 12. The resin cartridge 68 is filled with a special resin 70 for application. The special resin 70 can be supplied to the applicator 66 through a communication portion 72 between the applicator 66 and the resin cartridge 68. A cap 74 is provided to prevent the special resin adhering to the applicator 66 from scattering.

  A case where nail decoration is performed with the apparatus 10 will be described. When performing nail decoration, first, an ultraviolet curable resin is applied to the nail using the applicator 66. At this time, the irradiation port 25 faces upward and the safety switch 30 is turned off, so that no ultraviolet rays are irradiated.

  And after apply | coating an ultraviolet curable resin and putting a cap on the applicator 66, the irradiation port 25 is faced down and ultraviolet irradiation is started.

  By providing the applicator 66 in this way, the nail decoration can be performed anywhere more easily. The applicator 66 may be another applicator such as a pen or a spatula in addition to a brush. As the special resin 70 filled in the resin cartridge 68, in addition to an ultraviolet curable resin, an ultraviolet softening resin, a special resin that changes color when irradiated with ultraviolet rays, or the like can be used. Further, the resin cartridge 68 may be fixed inside the housing, or may be replaced with the entire cartridge. Further, the applicator 66 may be applied by immersing the applicator 66 in a separate container filled with the special resin without providing the resin cartridge 68.

  Next, another embodiment will be described with reference to FIG. FIG. 13A is a side view of the ultraviolet irradiation device 10, and FIG. 13B is a bottom view.

  The ultraviolet irradiation device 10 includes a holder 84 for keeping the distance between the irradiation port 25 and the claw 40 constant.

  The holder 84 includes a beam portion 86 having a predetermined length and a contact portion 88 provided at the tip thereof. The beam portion 86 is formed of a material having a certain elasticity, and the base end 90 is attached to the housing 12. On the other hand, the abutting portion 88 is formed in an arc shape, and is stable when being brought into contact with a human finger 44.

  A guide groove 92 for sliding the beam portion 86 is provided on the surface of the housing 12. Note that stoppers (not shown) are provided at predetermined intervals inside the guide grooves 92, and the beam portions 86 can be temporarily fixed at predetermined intervals. That is, the beam portion 86 is slidable along the guide groove 92 and can be temporarily fixed at a predetermined position. The distance from the irradiation port 25 to the contact portion 88 can be adjusted by sliding the beam portion 86.

  The guide groove 92 has a scale 94 indicating the irradiation area (the diameter of the irradiated portion). The scale 94 is a reference value of the irradiation area in the vicinity of the contact portion 88 when the beam base 90 is aligned at each scale position. That is, when the beam portion 86 is slid, the distance from the irradiation port 25 to the contact portion 88 is changed, and the irradiation area in the vicinity of the contact portion 88 is also changed. Therefore, the scale 94 has a diameter value (unit: mm) of the irradiation light, which is a reference value of the irradiation area that is changed by the sliding. For example, in the example shown in FIG. 13, since the base end 90 is at the position “φ10”, the claw 40 in the vicinity of the contact portion 88 can be irradiated with ultraviolet rays having a diameter of 10 mm.

  When performing ultraviolet irradiation using this apparatus 10, the base end 90 is previously slid to the scale position of a desired irradiation area. In this state, the contact portion 88 is brought into contact with the finger 44 and ultraviolet irradiation is started.

  At this time, since the contact portion 88 is in contact with the finger 44, the distance between the irradiation port 25 and the nail 40 can be kept constant. Therefore, ultraviolet irradiation can be performed in a stable state. Moreover, it can irradiate with a desired area by matching the base end 90 with the scale 94 of the desired irradiation area in advance.

  Further, since the beam portion 86 can be elastically deformed to some extent, fine adjustment of the irradiation position can be performed while the contact portion 88 is in contact with the finger. That is, if the irradiation port 25 is slightly moved, the movement amount is absorbed by the elastic deformation of the beam portion 86.

  As described above, according to the present embodiment, it is possible to perform ultraviolet irradiation while keeping the distance between the irradiation port and the nail constant.

  Next, another embodiment will be described with reference to FIG. This ultraviolet irradiation device 10 uses a light guide rod 76 as a guide means. Further, the applicator 66 and the irradiation port 82 are provided on the same end surface.

  The irradiation unit 14 of the apparatus 10 includes an ultraviolet LED 16 and a light guide rod 76. The light guide rod 76 is disposed in front of the ultraviolet LED 16 and can transmit the ultraviolet light emitted from the ultraviolet LED 16. Then, the ultraviolet ray 42 is irradiated from the irradiation port 82 which is the front end surface of the light guide rod 76. That is, the light guide rod 76 becomes an optical path of the ultraviolet light 42 and a part of the optical path of the ultraviolet light 42 can be visually recognized. Moreover, a desired position can be irradiated by bringing the tip (irradiation port 82) of the light guide rod 76 closer to the irradiation target position.

  Thus, by using the light guide rod 76, a part of the irradiation light path of the ultraviolet rays can be visually recognized.

  An applicator unit 78 including an applicator 66 and a resin cartridge 68 connected thereto is also provided. The coating unit 78 and the irradiation unit 14 can project from the front end surface of the housing 12 and be housed in the housing 12, respectively. And while either one protrudes, the other is housed inside the housing 12. Switching between the protrusion and the storage is performed by a knock switch 80 provided at the rear end of the housing 12. When the knock switch 80 is knocked once, the coating unit 78 is housed inside the housing 12 and the irradiation unit 14 (irradiation port 82) protrudes from the front end surface. When knock type switch 80 is knocked again, this time, irradiation unit 14 is housed and coating unit 78 protrudes.

  The knock type switch 80 is a projection / storage switch, and is also a main switch 26 for turning on the ultraviolet LED (see FIG. 9). When the irradiation unit 14 is protruded by knocking, the main switch 26 is turned on. When the irradiation unit 14 is accommodated by knocking again and the application unit 78 is protruded, the main switch 26 is turned off.

  Therefore, the main switch 26 is always turned off while the special resin is applied using the application unit 78. Therefore, even if the push switch 28 (sub switch) is pressed during application of the special resin, ultraviolet rays are not irradiated. Further, since the irradiation unit 14 and the coating unit 78 are provided on the same end surface, it is not necessary to change (turn over) the apparatus 10 when switching from special resin coating to ultraviolet irradiation. Therefore, operability can be further improved. In addition, it is possible to minimize the flying of special resin.

  In the present embodiment, the projection and storage of the irradiation unit 14 and the coating unit 78 are always switched, but both may be stored simultaneously. That is, when neither irradiation nor application is performed, both the irradiation unit 14 and the application unit 78 can be accommodated in the housing 12.

  As the guiding means, in addition to the light guide rod, other members may be used as long as they are light transmission members such as optical fibers. Further, as shown in FIG. 15, ultraviolet rays may be directly irradiated from the ultraviolet LED 16 without using a light guide rod, an optical fiber, or a lens.

  Next, another embodiment will be described with reference to FIG. The ultraviolet irradiation device 10 has a photocatalyst 100.

  That is, the photocatalyst 100 is applied to the inner peripheral side surface 20 a and the outer peripheral side surface 20 b of the holder 20 that holds the ultraviolet LED 16 and the red LED 18. At this time, the holder 20 is formed of a material having ultraviolet transparency. Therefore, the ultraviolet rays irradiated from the ultraviolet LED 16 can pass through the inside of the holder 20 and reach the photocatalyst 100 applied to the outer peripheral side surface 20b.

  The photocatalyst 100 generates a strong oxidizing power when irradiated with ultraviolet rays, and exhibits a deodorizing effect. Therefore, the odor of the special resin can be eliminated. Thereby, nail decoration can be performed more comfortably. Moreover, since the holder 20 is formed of an ultraviolet transmitting material, the application area of the photocatalyst 100 can be enlarged. That is, the photocatalyst 100 does not exhibit a deodorizing effect unless it is applied within the reach of ultraviolet rays. Therefore, the application region of the photocatalyst 100 is limited to the ultraviolet ray reachable range. Therefore, by forming the holder 20 with an ultraviolet transmitting material, the ultraviolet rays reach not only the inner peripheral side surface 20a of the holder 20 but also the outer peripheral side surface 20b. Thereby, the application area | region of the photocatalyst 100 and by extension, the application amount can be increased. And the deodorizing effect can be improved more.

  As described above, according to the present embodiment, the presence of the photocatalyst 100 exerts a deodorizing effect, so that the nail decoration can be performed more comfortably. In addition, a large amount of the photocatalyst 100 can be provided by forming the holder with an ultraviolet transmitting material. And a deodorizing effect can be improved more and nail decoration can be performed more comfortably.

  A part or all of the photocatalyst 100 provided on the outer side surface of the holder 20 may be replaced with a phosphor. The phosphor converts invisible ultraviolet light into visible light. By providing this phosphor in the holder 20, it is possible to confirm the irradiation state of ultraviolet rays. That is, the ultraviolet rays irradiated from the ultraviolet LED 16 are irradiated on the phosphor, whereby the invisible ultraviolet rays are converted into visible light. The user can confirm the irradiation state of the ultraviolet rays by visually recognizing the converted visible light. Therefore, the safety can be further improved by providing the phosphor on part or all of the side surface of the holder.

  Therefore, even if the ultraviolet LED 16 is erroneously turned on, the user can confirm the ultraviolet irradiation state by the visible light converted by the phosphor (ultraviolet before conversion). That is, it is possible to easily detect ultraviolet irradiation due to an erroneous operation. Even when the visible light LED is turned off, the lighting state of the ultraviolet LED 16 can be confirmed. That is, it is possible to confirm the ultraviolet irradiation state while confirming the color of the nail or the like to be irradiated without being affected by the color of the visible light LED.

  Note that the phosphor is not limited to the side surface of the holder as long as it is a position visible from the outside and a position where ultraviolet rays emitted from the ultraviolet light emitter reach. For example, if the holder is made of a material that can transmit visible light as well as ultraviolet light (many ultraviolet light transmitting materials can also transmit visible light), a phosphor may be provided inside or on the inner side surface of the holder. Alternatively, a material in which a phosphor is kneaded into a material having such characteristics may be used. Further, the holder may be formed from a material having only visible light permeability, and the phosphor may be provided on the inner side surface. According to this, it is possible to confirm the ultraviolet irradiation state while preventing the external irradiation of ultraviolet rays. Further, ultraviolet light emitted from the ultraviolet LED may be transmitted onto the surface of the housing by a light transmission member such as an optical fiber, and a phosphor may be provided here. Further, instead of applying the phosphor, a phosphor plate already coated with the phosphor may be used. Further, instead of using the photocatalyst and the phosphor together, only one of them may be provided.

It is a side view of the ultraviolet irradiation device which is an embodiment of the present invention. It is a figure which shows an example of arrangement | positioning of ultraviolet LED and visible light LED. It is a figure which shows an example of arrangement | positioning of ultraviolet LED and visible light LED. It is a figure which shows an example of arrangement | positioning of ultraviolet LED and visible light LED. It is a figure which shows an example of arrangement | positioning of ultraviolet LED and visible light LED. It is a figure which shows an example of a condensing mechanism. It is sectional drawing of a safety switch. It is sectional drawing of another safety switch. It is a figure which shows the circuit structure of an ultraviolet irradiation device. It is a figure which shows the state of use of an ultraviolet irradiation device. It is a schematic block diagram of the ultraviolet irradiation device which is other embodiment. It is a schematic block diagram of the ultraviolet irradiation device which is other embodiment. It is the side view and bottom view of the ultraviolet irradiation device which are other embodiments. It is a schematic block diagram of the ultraviolet irradiation device which is other embodiment. It is a schematic block diagram of the ultraviolet irradiation device which is other embodiment. It is a partial enlarged view of the ultraviolet irradiation device which is other embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 Ultraviolet irradiation device, 12 Case, 14 Irradiation unit, 22 Condensing unit, 25 Irradiation port, 26 Rotary switch, 28 Push switch, 30 Safety switch, 50 Cavity, 52 Weight, 56 contacts, 60 Timer, 66 Application tool , 68 Resin cartridge, 76 Light guide rod, 84 Holder.

Claims (35)

A portable housing;
An ultraviolet light emitter incorporated in the housing;
A guiding means that makes it possible to visually recognize at least a part of an irradiation path of ultraviolet rays by the ultraviolet emitter;
The ultraviolet irradiation device characterized by having. The ultraviolet irradiation device according to claim 1,
The ultraviolet irradiation apparatus, wherein the guide means is a light transmission member that guides ultraviolet rays emitted from the ultraviolet light emitter. The ultraviolet irradiation device according to claim 2,
The ultraviolet ray irradiation device, wherein the light transmission member is an optical fiber or a light guide rod. The ultraviolet irradiation device according to claim 1,
The ultraviolet irradiation apparatus, wherein the guide means is a visible light emitter that irradiates the vicinity of the ultraviolet irradiation position. The ultraviolet irradiation device according to claim 4,
The ultraviolet light irradiation apparatus, wherein the visible light emitter can be temporarily turned off while the ultraviolet light emitter is turned on. The ultraviolet irradiation device according to claim 5,
The ultraviolet light irradiation device, wherein the visible light emitter blinks at a predetermined interval. The ultraviolet irradiation device according to any one of claims 4 to 6,
The ultraviolet light irradiation apparatus, wherein the visible light emitter is provided at a position that irradiates near an outer periphery of an ultraviolet irradiation position by the ultraviolet light emitter. The ultraviolet irradiation device according to claim 7,
An ultraviolet irradiation apparatus, wherein a plurality of visible light emitters are provided on an outer periphery of an ultraviolet light emitter. The ultraviolet irradiation device according to claim 7,
The visible light emitter is provided at a position for irradiating a light guide plate provided on the outer periphery of the ultraviolet emitter. The ultraviolet irradiation device according to any one of claims 4 to 6,
The ultraviolet light irradiation device, wherein the visible light emitter and the ultraviolet light emitter are arranged so that their condensing points substantially coincide with each other. The ultraviolet irradiation device according to claim 10,
The ultraviolet light emitting device, wherein the ultraviolet light emitter is disposed so that an optical axis thereof is parallel to a central axis of the housing. The ultraviolet irradiation device according to claim 10,
An ultraviolet irradiation device, wherein the visible light emitter and the ultraviolet emitter are arranged so that their optical axes are symmetrical about the central axis of the housing. The ultraviolet irradiation device according to any one of claims 4 to 12,
The ultraviolet light irradiation device, wherein the visible light emitter has at least one color of red, green, and blue. The ultraviolet irradiation device according to any one of claims 1 to 13, further comprising:
A lens for collecting ultraviolet rays;
Distance adjusting means for adjusting the distance between the ultraviolet light emitter and the lens;
An ultraviolet irradiation device characterized by comprising a light condensing means. The ultraviolet irradiation device according to claim 14,
The distance adjusting means is a screwing member for screwing the light collecting means to the housing,
An ultraviolet irradiation apparatus characterized in that a distance between an irradiation port and a lens can be adjusted by rotating a screwing member. The ultraviolet irradiation device according to any one of claims 1 to 15, further comprising:
It has multiple switches for turning on the UV emitter,
An ultraviolet irradiation device characterized in that an ultraviolet light emitter is turned on only when all switches are in an on state. The ultraviolet irradiation device according to any one of claims 1 to 16,
An ultraviolet irradiation apparatus comprising a safety switch that is turned on only when an ultraviolet irradiation port provided in a housing is lowered a predetermined angle from a horizontal direction. The ultraviolet irradiation device according to claim 17,
Safety switch
A cavity provided inside the housing, the cavity having a side wall inclined at a predetermined angle;
A conductive weight capable of floating in the cavity;
A pair of contacts provided on the wall on the irradiation port side of the cavity;
And the safety switch is turned on only when the irradiation port is at a predetermined angle downward from the horizontal direction. The ultraviolet irradiation device according to any one of claims 1 to 18,
A main switch that maintains an on state or an off state by switch operation, and
A sub-switch that remains on only while pressed,
The ultraviolet irradiation device characterized by having. The ultraviolet irradiation device according to any one of claims 16 to 19,
An ultraviolet irradiation apparatus characterized in that an ultraviolet light emitter emits a pulse light every time all switches are turned on. The ultraviolet irradiation device according to any one of claims 1 to 20, further comprising:
An ultraviolet irradiation apparatus comprising a timer capable of setting a lighting time of an ultraviolet light emitter. The ultraviolet irradiation device according to any one of claims 1 to 21, further comprising:
An ultraviolet irradiation apparatus, wherein an applicator for applying a special resin whose properties are changed by irradiation with ultraviolet rays is provided in a housing. The ultraviolet irradiation device according to claim 22,
A resin cartridge filled with a special resin, which has a resin cartridge built in the main body and connected to the applicator,
An ultraviolet irradiation device, wherein a special resin is supplied from a resin cartridge to an applicator. The ultraviolet irradiation device according to claim 22 or 23,
The ultraviolet irradiation port and the applicator can protrude from the front end surface of the housing and can be stored inside the housing,
While either one of the ultraviolet irradiation port and the applicator protrudes, the other is accommodated in the housing. 25. The ultraviolet irradiation device according to any one of claims 1 to 24, further comprising:
An ultraviolet irradiation device, wherein a photocatalyst is provided at a position where ultraviolet rays emitted from an ultraviolet light emitter can reach. The ultraviolet irradiation device according to claim 25,
An ultraviolet irradiation device, wherein the photocatalyst is provided on a holder member for holding an ultraviolet light emitter. The ultraviolet irradiation device according to claim 25 or 26,
The holder member is formed of a material capable of transmitting ultraviolet rays,
An ultraviolet irradiation device, wherein the photocatalyst is provided on an inner side surface and an outer side surface of the holder member. The ultraviolet irradiation device according to any one of claims 1 to 27, further comprising:
The ultraviolet irradiation device has a phosphor at a position visible from the outside and a position where ultraviolet rays irradiated from the ultraviolet light emitter reach. The ultraviolet irradiation device according to claim 28,
The phosphor is provided on at least a part of the holder member for holding the ultraviolet light emitter,
An ultraviolet irradiation apparatus, wherein the holder member is capable of transmitting at least ultraviolet light from the ultraviolet light emitter to the phosphor, and is capable of transmitting at least visible light from the phosphor to the outside of the holder member. An ultraviolet irradiation device for performing nail decoration by curing an ultraviolet curable resin for nail decoration by irradiating with ultraviolet rays,
A portable housing;
An ultraviolet light emitter that emits ultraviolet light and is built into the housing;
A guiding means that makes it possible to visually recognize at least a part of an irradiation path of ultraviolet rays by the ultraviolet emitter;
The ultraviolet irradiation device characterized by having. The ultraviolet irradiation device according to claim 30, further comprising:
An ultraviolet irradiation apparatus comprising distance holding means for maintaining a constant distance between an ultraviolet light emitter and a nail that is an ultraviolet irradiation target. An ultraviolet irradiation unit that can be built into a portable housing,
An ultraviolet light emitter that emits ultraviolet light;
A guide means that makes it possible to visually recognize at least a part of an irradiation path of ultraviolet rays by the ultraviolet light emitter, the guide means comprising an optical fiber or a light guide rod that guides the ultraviolet rays emitted from the ultraviolet light emitter;
The ultraviolet irradiation unit characterized by having. An ultraviolet irradiation unit that can be built into a portable housing,
An ultraviolet light emitter that emits ultraviolet light;
A guide means for making it possible to visually recognize at least a part of an ultraviolet irradiation light path by the ultraviolet light emitter, the guide means being a visible light emitter provided at a position capable of irradiating the vicinity of the ultraviolet irradiation position;
The ultraviolet irradiation unit characterized by having. The ultraviolet irradiation unit according to claim 33,
The ultraviolet light irradiation unit, wherein the visible light emitter is provided at a position that irradiates near an outer periphery of an ultraviolet irradiation position by the ultraviolet light emitter. The ultraviolet irradiation unit according to claim 33,
The ultraviolet light irradiation unit, wherein the visible light emitter and the ultraviolet light emitter are arranged so that their condensing points substantially coincide with each other.

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